How many GCC optimization levels are there?

I tried gcc -O1, gcc -O2, gcc -O3, and gcc -O4

If I use a really large number, it won't work.

However, I have tried

gcc -O100

and it compiled.

How many optimization levels are there?

  • 13
    @minitech Which FM are you looking at? Even with man gcc on Cygwin (12000 odd lines) you can search for -O and find everything the answers below state, and then some.
    – Jens
    Jul 25, 2012 at 13:32
  • 1
    @minmaxavg after reading the source, I disagree with you: anything larger than 3 is the same as 3 (as long as it does not int overflow). See my answer. May 18, 2015 at 16:17
  • 2
    Actually, GCC has many other flags to fine tune optimizations. -fomit-stack-pointer will change the generated code. Jun 25, 2015 at 16:27
  • No compiler-construction here. Don’t tag indiscriminately.
    – user207421
    Apr 16 at 21:51

4 Answers 4


To be pedantic, there are 8 different valid -O options you can give to gcc, though there are some that mean the same thing.

The original version of this answer stated there were 7 options. GCC has since added -Og to bring the total to 8.

From the man page:

  • -O (Same as -O1)
  • -O0 (do no optimization, the default if no optimization level is specified)
  • -O1 (optimize minimally)
  • -O2 (optimize more)
  • -O3 (optimize even more)
  • -Ofast (optimize very aggressively to the point of breaking standard compliance)
  • -Og (Optimize debugging experience. -Og enables optimizations that do not interfere with debugging. It should be the optimization level of choice for the standard edit-compile-debug cycle, offering a reasonable level of optimization while maintaining fast compilation and a good debugging experience.)
  • -Os (Optimize for size. -Os enables all -O2 optimizations that do not typically increase code size. It also performs further optimizations designed to reduce code size. -Os disables the following optimization flags: -falign-functions -falign-jumps -falign-loops -falign-labels -freorder-blocks -freorder-blocks-and-partition -fprefetch-loop-arrays -ftree-vect-loop-version)

There may also be platform specific optimizations, as @pauldoo notes, OS X has -Oz.

  • 31
    If you're developing on Mac OS X there's an additional -Oz setting which is "optimize for size more aggressively than -Os": developer.apple.com/mac/library/DOCUMENTATION/DeveloperTools/…
    – pauldoo
    May 5, 2010 at 10:54
  • 9
    Note : O3 is not necessarily better than O2 even if the name suggest so. Try both.
    – johan d
    Sep 19, 2013 at 14:04
  • 2
    @pauldoo 404 page, replace with archive.org Jul 6, 2016 at 16:58
  • 1
    @pauldoo working link gcc.gnu.org/onlinedocs/gcc-4.1.0/gcc/Optimize-Options.html Jul 9, 2021 at 12:53
  • Calling "Os" optimize for size is IMO misleading since it is still optimising primarily for speed, but it just skips or alters certain optimisations that may otherwise lead to code size increasing. You did explain this well enough in your text, just pointing out a peeve I have in general by saying it means "optimize for size" implying that is the opposite of optimizing for speed. "O0" should never be used, as it generates ridiculous code like something from a 1970s compiler, and pretty much any remaining reason to use it is gone now that "Og" exists Aug 11, 2021 at 7:08

Let's interpret the source code of GCC 5.1

We'll try to understand what happens on -O100, since it is not clear on the man page.

We shall conclude that:

  • anything above -O3 up to INT_MAX is the same as -O3, but that could easily change in the future, so don't rely on it.
  • GCC 5.1 runs undefined behavior if you enter integers larger than INT_MAX.
  • the argument can only have digits, or it fails gracefully. In particular, this excludes negative integers like -O-1

Focus on subprograms

First remember that GCC is just a driver for cpp, as, cc1, collect2. A quick ./XXX --help says that only collect2 and cc1 take -O, so let's focus on them.


gcc -v -O100 main.c |& grep 100


COLLECT_GCC_OPTIONS='-O100' '-v' '-mtune=generic' '-march=x86-64'
/usr/local/libexec/gcc/x86_64-unknown-linux-gnu/5.1.0/cc1 [[noise]] hello_world.c -O100 -o /tmp/ccetECB5.

so -O was forwarded to both cc1 and collect2.

O in common.opt

common.opt is a GCC specific CLI option description format described in the internals documentation and translated to C by opth-gen.awk and optc-gen.awk.

It contains the following interesting lines:

Common JoinedOrMissing Optimization
-O<number>  Set optimization level to <number>

Common Optimization
Optimize for space rather than speed

Common Optimization
Optimize for speed disregarding exact standards compliance

Common Optimization
Optimize for debugging experience rather than speed or size

which specify all the O options. Note how -O<n> is in a separate family from the other Os, Ofast and Og.

When we build, this generates a options.h file that contains:

OPT_O = 139,                               /* -O */
OPT_Ofast = 140,                           /* -Ofast */
OPT_Og = 141,                              /* -Og */
OPT_Os = 142,                              /* -Os */

As a bonus, while we are grepping for \bO\n inside common.opt we notice the lines:

Common Alias(O)

which teaches us that --optimize (double dash because it starts with a dash -optimize on the .opt file) is an undocumented alias for -O which can be used as --optimize=3!

Where OPT_O is used

Now we grep:

git grep -E '\bOPT_O\b'

which points us to two files:

Let's first track down opts.c


All opts.c usages happen inside: default_options_optimization.

We grep backtrack to see who calls this function, and we see that the only code path is:

  • main.c:main
  • toplev.c:toplev::main
  • opts-global.c:decode_opts
  • opts.c:default_options_optimization

and main.c is the entry point of cc1. Good!

The first part of this function:

  • does integral_argument which calls atoi on the string corresponding to OPT_O to parse the input argument
  • stores the value inside opts->x_optimize where opts is a struct gcc_opts.

struct gcc_opts

After grepping in vain, we notice that this struct is also generated at options.h:

struct gcc_options {
    int x_optimize;

where x_optimize comes from the lines:

int optimize

present in common.opt, and that options.c:

struct gcc_options global_options;

so we guess that this is what contains the entire configuration global state, and int x_optimize is the optimization value.

255 is an internal maximum

in opts.c:integral_argument, atoi is applied to the input argument, so INT_MAX is an upper bound. And if you put anything larger, it seem that GCC runs C undefined behaviour. Ouch?

integral_argument also thinly wraps atoi and rejects the argument if any character is not a digit. So negative values fail gracefully.

Back to opts.c:default_options_optimization, we see the line:

if ((unsigned int) opts->x_optimize > 255)
  opts->x_optimize = 255;

so that the optimization level is truncated to 255. While reading opth-gen.awk I had come across:

# All of the optimization switches gathered together so they can be saved and restored.
# This will allow attribute((cold)) to turn on space optimization.

and on the generated options.h:

struct GTY(()) cl_optimization
  unsigned char x_optimize;

which explains why the truncation: the options must also be forwarded to cl_optimization, which uses a char to save space. So 255 is an internal maximum actually.


Back to opts.c:default_options_optimization, we come across maybe_default_options which sounds interesting. We enter it, and then maybe_default_option where we reach a big switch:

switch (default_opt->levels)


    enabled = (level >= 1);


    enabled = (level >= 3);

There are no >= 4 checks, which indicates that 3 is the largest possible.

Then we search for the definition of OPT_LEVELS_3_PLUS in common-target.h:

enum opt_levels
  OPT_LEVELS_NONE, /* No levels (mark end of array).  */
  OPT_LEVELS_ALL, /* All levels (used by targets to disable options
                     enabled in target-independent code).  */
  OPT_LEVELS_0_ONLY, /* -O0 only.  */
  OPT_LEVELS_1_PLUS, /* -O1 and above, including -Os and -Og.  */
  OPT_LEVELS_1_PLUS_SPEED_ONLY, /* -O1 and above, but not -Os or -Og.  */
  OPT_LEVELS_1_PLUS_NOT_DEBUG, /* -O1 and above, but not -Og.  */
  OPT_LEVELS_2_PLUS, /* -O2 and above, including -Os.  */
  OPT_LEVELS_2_PLUS_SPEED_ONLY, /* -O2 and above, but not -Os or -Og.  */
  OPT_LEVELS_3_PLUS, /* -O3 and above.  */
  OPT_LEVELS_3_PLUS_AND_SIZE, /* -O3 and above and -Os.  */
  OPT_LEVELS_SIZE, /* -Os only.  */
  OPT_LEVELS_FAST /* -Ofast only.  */

Ha! This is a strong indicator that there are only 3 levels.


opt_levels is so interesting, that we grep OPT_LEVELS_3_PLUS, and come across opts.c:default_options_table:

static const struct default_options default_options_table[] = {
    /* -O1 optimizations.  */
    { OPT_LEVELS_1_PLUS, OPT_fdefer_pop, NULL, 1 },

    /* -O3 optimizations.  */
    { OPT_LEVELS_3_PLUS, OPT_ftree_loop_distribute_patterns, NULL, 1 },

so this is where the -On to specific optimization mapping mentioned in the docs is encoded. Nice!

Assure that there are no more uses for x_optimize

The main usage of x_optimize was to set other specific optimization options like -fdefer_pop as documented on the man page. Are there any more?

We grep, and find a few more. The number is small, and upon manual inspection we see that every usage only does at most a x_optimize >= 3, so our conclusion holds.


Now we go for the second occurrence of OPT_O, which was in lto-wrapper.c.

LTO means Link Time Optimization, which as the name suggests is going to need an -O option, and will be linked to collec2 (which is basically a linker).

In fact, the first line of lto-wrapper.c says:

/* Wrapper to call lto.  Used by collect2 and the linker plugin.

In this file, the OPT_O occurrences seems to only normalize the value of O to pass it forward, so we should be fine.


Seven distinct levels:

  • -O0 (default): No optimization.

  • -O or -O1 (same thing): Optimize, but do not spend too much time.

  • -O2: Optimize more aggressively

  • -O3: Optimize most aggressively

  • -Ofast: Equivalent to -O3 -ffast-math. -ffast-math triggers non-standards-compliant floating point optimizations. This allows the compiler to pretend that floating point numbers are infinitely precise, and that algebra on them follows the standard rules of real number algebra. It also tells the compiler to tell the hardware to flush denormals to zero and treat denormals as zero, at least on some processors, including x86 and x86-64. Denormals trigger a slow path on many FPUs, and so treating them as zero (which does not trigger the slow path) can be a big performance win.

  • -Os: Optimize for code size. This can actually improve speed in some cases, due to better I-cache behavior.

  • -Og: Optimize, but do not interfere with debugging. This enables non-embarrassing performance for debug builds and is intended to replace -O0 for debug builds.

There are also other options that are not enabled by any of these, and must be enabled separately. It is also possible to use an optimization option, but disable specific flags enabled by this optimization.

For more information, see GCC website.

  • Indeed, though to be fair to the other answers, neither -Ofast nor -Og existed when those answers were written.
    – janneb
    Jun 17, 2013 at 19:15
  • So why does -O100 compile then?
    – einpoklum
    Feb 27, 2016 at 9:24
  • 3
    @einpoklum because GCC treats everything above -O3 as equal to -O3.
    – Demi
    Feb 27, 2016 at 19:25
  • Unfortunately, you still get a ton of <optimized out> in the debugger with -Og. Stepping still jumps around randomly. It's useless IMHO.
    – doug65536
    Oct 23, 2017 at 5:00

Four (0-3): See the GCC 4.4.2 manual. Anything higher is just -O3, but at some point you will overflow the variable size limit.

  • I have explored the source code in my answer and agree with you. More pedantically, GCC seems to rely on atoi undefined behavior, followed by a 255 internal limit. May 18, 2015 at 16:16
  • 7
    Please consider removing your answer, as it is (at least these days) incorrect.
    – einpoklum
    Feb 27, 2016 at 9:25

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.